微波强化有机改性膨润土对磷的吸附特性研究

利用十六烷基三甲基溴化铵(CTMAB)在微波辐射条件下对浙江临安膨润土进行改性,制得有机改性膨润土,利用其含磷模拟废水进行处理,考察了不同的工艺条件如有机改性剂用量、微波辐射强度、辐照时间、吸附时间、改性膨润土投加量、pH值对废水中磷去除效果的影响。结果表明:在有机改性剂用量为3 mmol/g,微波辐照强度为96 W/g,微波辐照时间8 min为最佳制备条件。改性膨润土用量为12 mg/L,反应时间为15 min,溶液pH为7及常温条件下,改性膨润土对浓度为50 mg/L的含磷废水去除率达到97.3%,吸附符合Freundlich吸附等温方程。     

有机-无机复合膨润土的制备及其对磷吸附特性研究

新型绿色表面活性剂C12烷基多糖苷季铵盐表面活性剂和AlCl3·6H2O作为改性剂对膨润土进行改性，制备新型环保无机-有机复合吸附剂，并将其用于含磷废水的处理，考察了A1Cl3·6H2O投加量、有机改性剂用量、改性膨润土的投加量、反应时间及pH等因素对除磷效果的影响。结果表明，经8 mmol/g(Al/膨润土)的AlC...     

阴/阳离子有机膨润土制备及其对苯酚吸附性能的实验研究

采用十六烷基三甲基溴化铵(CTMAB)和十二烷基硫酸钠(SDS)对辽宁黑山钙基膨润土进行不同工艺的阴/阳离子有机膨润土制备,并探讨其对被苯酚污染的地下水的吸附机理及其影响因素,为阴/阳离子有机膨润土在污染地下水修复新技术--渗透反应格栅(PRB)中应用的可行性提供必要的技术参数.研究结果表明,制备阴/阳离子有机膨润土的最佳工艺是加入3.0%(质量分数)的Na2CO3钠化,以120CTMAB/15SDS的投加量对其进行阴/阳离子有机改性;阴/阳离子有机膨润土对水中有机物具有协同去除效应;阴/阳离子有机膨润土Na-ACOMMT对苯酚吸附的最佳条件是投加60 g/L、80～100目的Na-ACOMMT,在温度20℃、pH为6～8、振荡转速200 r/min的条件下振荡30 min,此时苯酚的去除率高达78.74%,且吸附等温线符合Langmuir和Freundlich方程;Na-ACOMMT可通过多次吸附(累积吸附量为0.045 9 mg/g)达到降低成本的目的.但是Na-ACOMMT吸附被苯酚污染的地下水时,可能会有微量阴/阳离子表面活性剂的解吸.     

阴-阳离子有机膨润土吸附水中苊的性能及机理研究

用溴化十二烷基三甲铵（DTMAB）、十二烷基硫酸钠（SDS）、十二烷基苯磺酸钠（SDBS）按不同配比制得一系列阴一阳离子有机膨润土,研究了有机膨润土吸附水中苊的性能及机理。结果表明,阴一阳离子有机膨润土对水中苊的吸附去除能力大于单阳离子有机膨润土,且与改性时所用阴离子表面活性剂的种类、浓度有关;阴一阳离子有机膨润土对苊的吸附等温线呈线性,吸附机理主要是分配作用。     

铁镍改性膨润土对废水中有机污染物的吸附性能研究

以钠基膨润土为原料,制备了铁镍无机改性土和铁镍有机复合改性土,并应用于造纸废水的处理,探讨了改性土用量、废水pH值、搅拌时间等因素对COD去除率的影响,通过正交实验对实验条件进行了优化.结果表明:铁镍有机复合改性土和铁镍元机改性土对废水的处理效果明显好于原土;膨润土的用量、废水的pH对COD的去除率影响较大;对于铁镍无机改性土,吸附剂用量为12g/L,溶液pH=2,吸附时间为10 min时,对废水中COD的去除率为54.06%;对于铁镍有机复合改性土,吸附剂用量为14g/L,溶液pH=3,吸附时间为20 min时,对废水中COD的去除率为70.10%.     

糖脂类生物表面活性剂去除污染含水层中石油烃的研究

研究了糖脂类生物表面活性剂对石油烃的增溶,并将其用于污染含水层中石油烃的去除。结果表明:石油烃溶解度随着糖脂类生物表面活性剂浓度的增大而增大,糖脂类生物表面活性剂质量浓度为1 200mg/L时,石油烃溶解度达10 077.7mg/L;界面张力随着糖脂类生物表面活性剂浓度的增加而减小,糖脂类生物表面活性剂质量浓度为1mg/L时,界面张力为34.3mN/m,糖脂类生物表面活性剂质量浓度为800mg/L时,界面张力为5.2 mN/m。采用糖脂类生物表面活性剂对污染含水层进行清洗处理,在固液比(质量体积比)为1g∶2mL的体系中,糖脂类生物表面活性剂质量浓度为3 000mg/L,120r/min、10℃下振荡12h,石油烃去除率达70.82%。污染含水层柱冲洗结果表明,糖脂类生物表面活性剂质量浓度分别为1 200、3 000mg/L时,10倍孔隙体积的表面活性剂冲洗后,分别从污染砂样中去除41.81%和63.30%的石油烃。     

有机膨润土吸附苯胺的性能及工艺条件的优化

以钙基膨润土为原料,钠化后用溴化十六烷基三甲铵(CTMAB)进行有机改性,制得有机膨润土。在单因素吸附实验的基础上,采用L16(44)正交实验法对有机膨润土吸附水中苯胺的工艺条件进行了优化研究。结果表明,当矿物的粒径小于74μm、振荡速度为150 r/m in、吸附液为25 mL,并且以此三者为固定因素时,其优化工艺条件为有机膨润土投加量2.0 g,温度40℃,pH 7,吸附时间1.5 h。     

铁镍改性膨润土对废水中有机污染物的吸附性能研究

以钠基膨润土为原料,制备了铁镍无机改性土和铁镍有机复合改性土,并应用于造纸废水的处理,探讨了改性土用量、废水pH值、搅拌时间等因素对COD去除率的影响,通过正交实验对实验条件进行了优化.结果表明：铁镍有机复合改性土和铁镍元机改性土对废水的处理效果明显好于原土;膨润土的用量、废水的pH对COD的去除率影响较大;对于铁镍无机改性土,吸附剂用量为12g/L,溶液pH=2,吸附时间为10 min时,对废水中COD的去除率为54.06%;对于铁镍有机复合改性土,吸附剂用量为14g/L,溶液pH=3,吸附时间为20 min时,对废水中COD的去除率为70.10%.     

DSB+CPB复合改性膨润土对磷酸盐的吸附

为研究两性-阳离子表面活性剂复合改性膨润土的吸附除磷性能及其机理,采用不同比例两性表面活性剂——十二烷基二甲基磺丙基甜菜碱(DSB)和阳离子表面活性剂溴代十六烷基吡啶(CPB)对膨润土进行了有机复合改性,制得DSB+CPB复合改性膨润土,利用X射线衍射分析(XRD)、傅里叶红外分析(FT-IR)、扫描电子显微镜(SEM)、接触角(CA)以及热重分析(TGA)等手段对膨润土土样进行了表征,并用吸附等温模型和动力学方程拟合其吸附过程,探讨了改性比例、pH和温度等因素对吸附的影响。结果表明:DSB改性能提高膨润土对磷酸盐的吸附能力,当加入CPB复合改性后,可进一步促进DSB改性膨润土对磷酸盐的吸附能力,且吸附能力均随改性比例的增大而增强;对于0.5 DSB和1.0 DSB的改性膨润土,其与CPB最佳复合比例均为DSB+1.5CPB,最大吸附量分别为原土的7.81倍和8.19倍;改性膨润土对磷酸盐的吸附均符合Langmuir等温模型和伪二级吸附动力学方程,其吸附能力随pH的升高而降低,且吸附为物理和化学吸附同时存在的自发吸热熵增过程。上述研究结果可为两性-阳离子表面活性剂复合改性膨润土吸附除磷提供参考。     

改性膨润土联合混凝剂处理微污染水中有机物

采用十二烷基多糖苷季铵盐作为改性剂制备改性膨润土,研究了改性膨润土联合混凝剂去除有机物的效果,考察了有机改性剂用量、微波辐射功率、辐射时间、膨润土投加量、pH值对有机物去除效果的影响,探讨了改性膨润土的改性和去除机理。结果表明,经微波改性后,实现了十二烷基多糖苷季铵盐阳离子对膨润土的插层,增大了层间距,提高了膨润土的吸附性能。联合混凝剂投加改性膨润土能够改善絮凝性能,显著提高有机物的去除效果。在最佳条件下,改性膨润土与PAC联合后的强化混凝,对初始浓度15.3 mg/L的微污染水中有机物的去除率达到95%以上,吸附符合Freundlich吸附等温方程。     

沸石改性及其去除水中氨氮的实验研究

通过实验研究了沸石改性条件及其对水中氨氮吸附去除的影响。结果表明，加热改性与无机酸改性不能显著提高沸石对氨氮的吸附量。利用NaOH改性的最佳浓度为1 mol/L，此条件下对氨氮吸附量可提高到650.68 mg/kg，为天然沸石的2.82倍。利用无机盐改性时，对氨氮吸附效果最好的是NaCl改性沸石，其次为KCl改性沸石与CaCl₂改性沸石。随着NaCl溶液浓度和改性时间的增加，改性沸石对氨氮的吸附量显著增加，可达天然沸石的3～4倍；在NaCl浓度为150 g/L与改性时间为18 h条件下，改性沸石对氨氮吸附量可达887.35 mg/kg，为天然沸石的3.84倍。     

Preparations of organobentonite using nonionic surfactants

Due to hydrophilic environment at its surface, natural bentonite is an ineffective sorbent for nonpolar nonionic organic compounds in water even though it has high surface area. The surface properties of natural bentonite can be greatly modified by simple ion-exchange reactions with large organic cations (cationic surfactants) and this organobentonite is highly effective in removing nonionic organic compounds from water. Cationic surfactant derived organobentonites have been investigated extensively for a wide variety of environmental applications. In this study, the preparation of organobentonite using nonionic surfactants has been investigated for the first time. Results indicate that nonionic surfactants intercalates into the interlamellar space of bentonite and may demonstrate higher sorption capacity than cationic surfactant. It is possible to create large interlayer spacing and high organic carbon content organobentonite by use of nonionic surfactants with suitable balance between the hydrocarbon and ethylene oxide chain lengths. In addition, nonionic surfactant derived organobentonites are more chemically stable than cationic surfactant derived organobentonites.     

掺Al-TiO2改性膨润土去除微污染水中COD和NH4-N

采用掺Al-TiO2作为改性剂制备改性膨润土,考察了微波辐射功率、辐射时间、TiO2改性剂用量、铝盐掺杂量、pH值对微污染水中COD和NH4-N去除效果的影响。实验表明,微波辐射功率为460 W,辐射时间为8 min,TiO2改性剂用量为1.3 mmol/g,铝盐掺杂量为0.2 mmol/g为最佳制备条件。pH值为6.0,改性膨润土投加量为40 mg/L,沉淀时间为30min时,对微污染水中初始浓度15 mg/L的COD和5 mg/L的NH4-N去除率分别达到92%和59%以上。     

Parameter optimization of the fungicide (Vapam) sorption onto soil modified with clinoptilolite by Taguchi method

This study employs the Taguchi optimization methodology to optimize the effective parameters for the pesticide (Vapam) sorption onto soil modified with natural zeolite (clinoptilolite). The experimental factors and their ranges chosen for determination of the effective parameters were: initial Vapam concentration (0.4–1.6 mg/L), initial pH of the pesticide solution (2–12), the percentage of clinoptilolite in the modified soil (0–6 %), temperature (15–35°C) and shaking time (2–24 h). The orthogonal array (OA) L₁₆ and the bigger the better response category of the Taguchi method were selected to determine the optimum conditions: initial Vapam concentration (1.2 mg/L), initial pH of the pesticide solution (2), the percentage of clinoptilolite in the modified soil (4 %), temperature (15°C) and shaking time (2 h). The results showed that in comparison with other parameters, the initial Vapam concentration was the most effective one for the sorption of this pesticide onto soil, modified with clinoptilolite. Moreover, after determining the optimum levels of the sorption process parameters, confirmation experiments were performed to prove the effectiveness of the Taguchi's experimental design methodology.     

Sorption kinetics and isotherm modelling of imidacloprid on bentonite and organobentonites

Bentonite was modified by quaternary ammonium cations viz. cetytrimethylammonium (CTA), cetylpyridinium (CP), rioctylmethylammonium (TOM) and pcholine (PTC) at 100% cation exchange capacity of bentonite and was characterized by X-ray diffraction, CHNS elemental analyser and Fourier transform infrared spectroscopy. The sorption of imidacloprid on organobentonites/bentonite was studied by batch method. Normal bentonite could adsorb imidacloprid only upto 19.31–22.18% while all organobentonites except PTC bentonite (PTCB), enhanced its adsorption by three to four times. Highest adsorption was observed in case of TOM bentonite (TOMB) (76.94–83.16%). Adsorption kinetic data were fitted to pseudo-first-order, pseudo-second-order and intraparticle diffusion models. For normal bentonite data were best fitted to pseudo-first-order kinetic, while for organobentonites fitted to pseudo-second-order kinetics. Sorption data were analysed using Freundlich, Langmuir, Temkin and Dubinin–Radushkevich isotherm models. Data were well fitted to Freundlich adsorption isotherm. Product of Freundlich adsorption constant and heterogeneity parameter (K_f.1/n) was in following order: TOMB (301.87) > CTA bentonite (CTAB) (152.12) > CP bentonite (CPB) (92.58) > bentonite (27.25). Desorption study confirmed hysteresis and concentration dependence. The present study showed that the organobentonite could be a good sorbent for removal of imidacloprid from natural water sample also. Percentage adsorption and Distribution coefficient (mL g^?1) value of different adsorbent was in following order: TOMB (74.85% and 297.54) > CTAB (55.78% and 126.15) > CPB (45.81% and 84.55) > bentonite (10.65% and 11.92).     

Treatment of phenol-containing wastewater by photoelectro-Fenton method using supported nanoscale zero-valent iron

This study presents the degradation of phenol by the photoelectro-Fenton method using nano zero-valent iron (nZVI) immobilized in polyvinyl alcohol–alginate beads. The effect of nZVI loading, H₂O₂ concentration, pH, and initial phenol concentration on phenol degradation and chemical oxygen demand reduction was studied. The scanning electron microscope images of the nZVI beads were used to analyze their morphology, and their diameters were in the range of 500–600 μm. The concentration of nZVI in the beads was varied from 0.1 to 0.6 g/L. Fe²⁺ leakage of 1 and 3 % was observed with 0.5 and 0.6 g/L of nZVI, respectively, and the observed beads' fracture frequency was 2 %, which confirmed the stability of the beads. The optimum operating conditions that arrived for better degradation were 0.5 g/L of nZVI, pH 6.2, and 400 mg H₂O₂/L. The treatment of effluent by this method increased the biodegradability index of the effluent, and the degradation data were found to follow pseudo first-order kinetics.     

陶瓷负载Ag、Ce共掺杂TiO_2光催化剂降解甲基橙的研究

以陶瓷为载体,采用溶胶-凝胶法制备了银离子和铈离子共掺杂TiO2的负载型光催化剂——T-AC/陶瓷,研究了pH值、双氧水用量、催化剂用量、紫外灯强度、废水的初始浓度等因素对T-AC/陶瓷光催化剂降解甲基橙染料废水的影响。结果表明,当pH为2、双氧水用量为0.5 mL/100 mL、催化剂用量为3 g/L、紫外灯功率为20 W、废水初始浓度为10mg/L时,甲基橙的降解率可达85.9%,并且甲基橙的光催化降解属于一级动力学方程,T-AC/陶瓷催化剂有较高的活性和稳定性,在废水处理中具有较好的应用前景。     

零价铁复合有机膨润土处理染料废水的研究

针对目前印染废水处理现状及膨润土在水处理中回收困难等问题，提出将零价铁复合到有机膨润土中制成零价铁复合有机膨润土(ZVI-OB)，以达到高效吸附并降解污染物的目的。以染料废水(Orange II) 作为研究对象，考察了废水中染料的初始浓度、pH以及吸附时间对ZVI-OB去除染料效率的影响，并研究了吸附后降解过程中时间和pH对污染物降解的影响以及降解前后膨润土层结构的变化。研究结果表明，ZVI-OB相对于CTMAB改性的有机膨润土而言，其吸附量有所降低，但ZVI-OB在吸附污染物之后能有效降解有机物。ZVI-OB在饱和吸附Orange II后经催化氧化，总有机碳含量降低为原来的19%，可以重复利用。     

Parameter optimization of the fungicide (Vapam) sorption onto soil modified with clinoptilolite by Taguchi method

This study employs the Taguchi optimization methodology to optimize the effective parameters for the pesticide (Vapam) sorption onto soil modified with natural zeolite (clinoptilolite). The experimental factors and their ranges chosen for determination of the effective parameters were: initial Vapam concentration (0.4-1.6 mg/L), initial pH of the pesticide solution (2-12), the percentage of clinoptilolite in the modified soil (0-6 %), temperature (15-35°C) and shaking time (2-24 h). The orthogonal array (OA) L(16) and the bigger the better response category of the Taguchi method were selected to determine the optimum conditions: initial Vapam concentration (1.2 mg/L), initial pH of the pesticide solution (2), the percentage of clinoptilolite in the modified soil (4 %), temperature (15°C) and shaking time (2 h). The results showed that in comparison with other parameters, the initial Vapam concentration was the most effective one for the sorption of this pesticide onto soil, modified with clinoptilolite. Moreover, after determining the optimum levels of the sorption process parameters, confirmation experiments were performed to prove the effectiveness of the Taguchi's experimental design methodology.     

粉煤灰制备混凝剂及其对黄河水的处理效果

以粉煤灰和铁泥为原料、加入一定量NaCl作助溶剂室温下制备粉煤灰混凝剂,考察酸灰比与酸浓度对Fe3+、Al3+溶出率及混凝剂对黄河水处理效果的影响。结果表明,Fe3+、Al3+的最佳溶出条件为酸灰比3 mL/g、HCl浓度4 mol/L,此时Fe3+溶出率为28.1%,浓度为11.81 g/L;Al3+溶出率为5.2%,浓度为1.86 g/L。粉煤灰混凝剂对黄河水的处理效果在投加量2.38 mL/L、沉降时间30 min、pH 6.2～7.5时最佳,对浊度、SS和CODMn平均去除率分别为89.7%、83.6%和62.3%,优于传统市售混凝剂PAC和FC,Fe3+、Al3+同时存在有利于各自优势的发挥从而提高混凝效果。